DE3220322A1 - TIME BASE CORRECTION DEVICE IN A PLAYBACK PLAYER FOR RECORDED DATA - Google Patents

Description

_ 5 -

Time base correction device in a reproduction device for recorded data

description

The present invention relates to a time base corrector for recorded data reproducing devices, and more particularly to a time base corrector for eliminating a time base change that occurs when reproducing color television data and producing audio data recorded on a recording medium.

When reproducing color television data, it is essential that that the resulting color image is stable, correct, and uniform in color. Is the recording medium a video disk, then the center of rotation of the video disk when it is placed on moved the turntable away from the center of the recording track A color television signal corresponding to the video disc

• Time base variation of 20 / us or more _3, which is an extremely large value compared to the maximum permitted value of 5 / us for correct reproduction of the color television signal.

In a video disc playback system, it is therefore essential that to provide means for eliminating the time base change.

The circuit arrangement for such a device

is shown in FIG. 1, for example. According to Fig. 1, a reproduced RF signal (radio frequency) from a playback head not shown to the band pass filters 1 and 2 and converted into a color video RF signal and split a tone RF signal. The video RF signal and the audio RF signal are demodulated into a video signal and an audio signal by demodulators 3 and 4, respectively. The resulting color video signal is sent to a burst gate 5 for separation of a burst color signal (burst) applied. The phase of the burst color signal and the phase of a subcarrier signal from one Reference signal oscillators 6 are subjected to a comparison in a phase comparator 7. This gives a phase difference signal which corresponds to the time base deviation value ■ of the reproduced signal. Is thus from

this phase difference signal an actuator 8 is driven to the acceptance fixed point position to move in the direction tangential to the recording track, then the time base can be corrected in this way. 20th

In known arrangements, no IRA pulse burst signal is present for a time of 9H (approximately 570 μs), namely during the vertical blanking period or the return time of the color television signal. Thus varies during this Period completely free the phase difference signal so that it receives a noise component. This means, that an undesirable time base discrepancy occurs. Such a time base deviation does not bring any Problems for the video signal as it occurs during the vertical blanking period; however, it does periodic noise signals in the sound signal, which creates a serious problem.

The invention is therefore based on the object of providing a 35

Specify time base correction device in which the

The disadvantages of known devices noted above have been eliminated and in which video and audio signals are mixed that are stable and have been corrected. 5

The time base correcting apparatus for a recorded data reproducing device is according to the present invention characterized in that the video data and the sound data are reproduced in one from a consumer Signal are separated from each other so that the time base corrections of the video data and the sound data are performed independently, and that the time base correction of the Video data with a variable delay element according to the phase difference between a reproduced one Color burst and a reference signal is performed while the time base correction of the tone data is performed with a changeable delay element according to the phase difference between a horizontal synchronization signal and a Reference signal takes place.

An embodiment of the invention is now under Described with reference to the drawings. Show it:

Fig. 1 is a block diagram of a known time base corrector

2 shows a block diagram of an exemplary embodiment of the device according to the invention.

In FIG. 2, the elements similar to those in FIG. 1 are also shown provided with the same reference symbol. A reproduced RF signal from a not shown pickup is sent to the Band pass filters 1 and 2 are applied to convert it into a color video RF signal and split a tone RF signal. The video-

35 'RF signal and the tone RF signal are charge coupled Devices (CCD) 9 and 10 representing the variable delay elements on demodulators

3 or 4 created. The output of the demodulator 3, i.e. the demodulated video signal, is sent to a color burst gate 5 and applied to a horizontal sync separator 11 so that the color burst signal and extracting a horizontal synchronization signal. The pulse burst signal and a subcarrier signal from a reference signal oscillator 6 are fed to a phase comparator 7 and there a phase comparison subjected, the result of which as a phase difference signal of the phase comparator 7 is output. A voltage controlled oscillator (VCO) 12 has an output oscillation frequency corresponding to the level of the Phasendif reference signal. The vibration output of the VCO is used as a clock pulse to control the delay value of the CCD 9.

On the other hand, as described above, these are extracted Horizontal synchronization signal and the frequency division signal from a frequency divider 13, which the output signal of the oscillator 6 divided in terms of frequency, subjected to a phase comparison in a comparator 14. Thus, the frequency division signal frequency is set equal to the horizontal sync signal frequency. Instead of dividing the oscillation output signal of the subcarrier oscillator 6 in terms of frequency, a different one can also be used Oscillator can be used. The oscillation frequency of a VCO 15 is set according to the value of the phase difference signal regulated and the vibration output signal phase of the VCO15 is used as a clock pulse to control the delay of the CCD 10.

Thus, the time base of the color video data can be calculated with a Accuracy can be corrected, which is defined by the frequency of the color burst signal, and which · The resulting color image is correct and uniform in color

stable. Because the horizontal sync signal is present during the vertical sync interval the time base of the audio signal can also be corrected.

In general, the video and sound signals are recorded by the FM modulation system. Will the time base corrections of these signals carried out after the signals are sent to the variable delay elements 9 and 10 have been applied, then a method can be used in which, as FIG. 2 shows, the frequency-modulated Signals are used as they are, or a method in which the time base correction is carried out after one or both of the modulated signals have been demodulated. In the case of a video disc, in which at least two audio channels are recorded, can be used in a system for correcting the time base in the frequency-modulated Signal stage, as Fig. 2 shows, after the time base correction has been carried out for two channels, the signals are assigned to the channels, or the time base correction is made for each channel after assignment of the signals carried to the channels. In a system for correcting the time base after demodulating the signals time base correction should be performed for each channel.

Some computational considerations will now be made on the numbers that result when charge coupled devices (CCD) are used as the time base corrector for video and audio data. First, the CCD of the video system will be described. Since the frequency band of the baseband of the video system is 0 to 4.2 MHz, the lowest frequency should be f ₁ . of the clock signal must be at least 10 MHz. Is the highest working frequency f ^ _{max of} the clock signal present at dev

- 1ο -

If the device is 15 MHz and the time base error to be corrected is 35 µs, then the following equation applies:

n, (1/10 - 1/15) = 35

where n _{1 is} the number of stages in the CCD.

Thus for n. = 1050
'

t, = 1050 χ 1/10 - 1/2 χ 35 = 87.5, US

i 3. /

^f 1a ^{= 1050/8} 7 »5 = 12 MHz,

where t _{1 is} the average delay time and

f. are the clock frequency at this point in time.

Is the highest frequency of the error signal f ₁

ι Q max

2 kHz, then the corresponding mean delay phase is Φ «. - 63 °, as can be seen from the following expression:

1e max = ^fc 1a 25

The value of 63 has proven to be useful in the time base correction servo loop.

The audio or sound system will now be described.

It is assumed that the audio signal is corrected with FM and RF signals of 2.3 MHz and 2.81 MHz. Becomes the same ratio as in the case of the video system for the lowest frequency f ". of the clock

signals applied, this results in 35

T _{2 min} = 10 / 4.2 χ 2.81 = 6.7 MKz

The time base error to be corrected is 35 / US and thus is

n ₂ (1 / 6.7 - 1 / f _2max ) = 3 _{5 /} us

F _{o mfav} = 15 MHz, then n _o = 424 (steps). It is therefore advantageous for the sound system to use n “and f _? _ To be determined taking into account the energy consumption and the number of levels that can be integrated after the time base correction of the video system has been guaranteed.

It can thus be seen from the foregoing that, according to the invention, a sound signal free of interfering signals can be obtained while producing a correct color television picture.

In operation, an optical pickup reads signals from a plate without touching the plate. For this reason owns the optical pickup has a focusing servo, which forms a beam spot on the disk with high accuracy at all times, furthermore a tracking servo mechanism, with which the beam point can follow the track ^ and a tangential servo mechanism for moving the beam spot in a direction tangential to the track. Thus, the focusing lens the tracking mirror and the tangential mirror under the control of the corresponding servo systems for Swing brought. If one of the vibration systems makes undesired movements as a result of interference signals, then such undesirable work appears as uneven coloring or failure of one reproduced signal. It is thus desirable that

the construction of the mechanical vibration systems is as simple as possible. In this context According to the invention, the tangential mirror can be omitted. Thus, the playback signal is stable according to the invention. This effect can be applied to other contacting species in the same way can be achieved by playback devices.

Claims (9)

GRUNECKER, KINKELDEY, STOCKMAlR & -PARI NER-- PATENT LAWYERS EUROPEAN PATEMT ATTORNEYS A. GRÜNECKER, oipl-ing DR. H. KINKELDEY. opl-ing OR W. STOCKMAIR. dipi.-ing..ae6icai. DR. K. SCHUMANN, qpu-pmvs P. H. JAKOB, »pl-ing DR. G. BEZOLD. o «= l-chem W. MEISTER, DiPL-ING H.HILGERS. opl-ing DR. H. MEYER-PLATH. op --ing. 80OO MUNICH 22 MAXIMIUANSTRASSE 43 10 May 28, 1982 P 17 324-57 / so 20th PIONEER VIDEO CORPORATION
No. 4-1, Meguro 1-chome,
Meguro-ku, Tokyo, Japan Time base correction device in a reproducing device for recorded data 30th Claims ger n \ Time base correction device for a reproduction device for use with a recording medium on which color video data and sound data are recorded, characterized by Means (1, 2) for separating and extracting a color burst signal and a horizontal synchronization signal from an output signal reproduced by a pickup,
5 Video signal time base correction devices (5, 6, 7, 9, 12) for correcting the time base of the color video -> th according to a first phase difference between the color burst signal and a first predetermined one Reference signal and Sound signal time base correction means (10, 11, 13, 14, 15) for correcting the time base of the sound data according to FIG a second phase difference between the horizontal synchronization signal and a second correct reference signal. 2. Apparatus according to claim 1, characterized in that the video signal time base correction devices (5, 6, 7, 9, 12) correct the time base of a signal modulated with a video signal and that the audio signal time base correction means (10, 11, 13, 14, 15) the time base of one with an audio signal Correct the modulated signal. 3. Apparatus according to claim 1 or 2, characterized in that the video signal time base correction means (5, 6, 7, 9, 12) and the audio signal time base correction devices (10, 11, 13, 14, 15) variable delay elements (9, 10) for delaying the modulated signals in response to the Phase differences around values corresponding to this first and second phase difference. 4. Apparatus according to claim T, characterized g e k e η nz e i c h ne t that the video signal time base correction devices (5, 6, 7, 9, 12) the time base of a Correct the video signal resulting from demodulation of the reproduced signal and that the audio signal time base corrector (10, 11, 13, 14, 15)) correct the .time base of a sound signal that is by demodulating the reproduced signal. 5. Apparatus according to claim 4, characterized in that that the video signal time base correction devices (5, 6, 7, 9, 12) are variable delay elements (9) for delaying the video signal by an amount corresponding to the first phase difference and the audio signal time base corrector (10, 11, 13, 14, 15) variable delay elements (10) for delaying the audio signal by a value corresponding to the second Have phase difference. 6 .. Device according to one of the preceding claims, characterized in that the audio signals have one or more channels. 7. Device according to one of the preceding claims, characterized in that the video signal time base correctors a voltage controlled oscillator for receiving a signal corresponding to the first phase difference, and that the delay elements are charge coupled devices connected to the oscillator. 8. Device according to one of the preceding claims, characterized in that the audio signal time base correction devices have a voltage have controlled oscillator which receives a signal according to the second phase difference, and that the Delays include charge coupled devices connected to the oscillator. 5 9. Apparatus according to claim 8, characterized by a sub-circuit for generating the second predetermined reference signal from the first predetermined Reference signal. IO